CZ286383B6 - Access opening for use in surgery - Google Patents

Abstract

A system of an access opening (40) used in surgery comprises a sleeve (41, 42) with an outlet hole situated at distant end of the sleeve that is inserted in a section made in the patient body, when said outlet hole enables access in the patient body cavity. The system (40) also comprises the outlet hole packing, which is inserted in the section. Further it comprises inlet device situated at proximal end of the sleeve (41, 42) and an inlet packing for sealing the system in the region of the inlet hole so that after filling of the patient body cavity with gas, both the outlet and inlet packing prevents escape of gas from the body cavity, while the inlet packing also provides access for surgeon hand or surgeon instrument and at the same time seals the area around the arm that remained outside of the access opening system.

Description

Technical field

The present invention relates to an access opening that includes an opening allowing minimally aggressive surgical operations, a surgical instrument using such an opening as well as a surgical drape using the access opening and instruments of the present invention are described. Minimally aggressive surgical procedures are those that are performed to bring minimal trauma caused by incision to the patient's body. The device of the present invention makes it possible to perform a surgical procedure using a hand-held laparoscopic instrument which can substantially increase the amount and variety of surgical procedures that can be performed without the use of open surgery. Minimally aggressive surgery almost always involves introducing gas into the patient's peritoneal cavity, causing pneumoperitoneum.

BACKGROUND OF THE INVENTION

U.S. Pat. No. 5,176,649 discloses a flexible insert that serves to insert an endoscope or endoscopic instrument over a body wall, such as a chest or abdominal wall. The tool insertion device comprises a deformable, rigid, plastic or metal trocar and a thin plastic sheath with an adhesive sleeve that surrounds the trocar. This device makes it possible to maintain the seal against air leakage and allows the insertion of rigid curved tools into the device so that they are not expelled by the muscles. This reduces the need for repeated injection and insertion procedures that could cause further injury to the patient's skin.

DE 37 37 121 discloses a ring-shaped sealing sleeve made of a resilient material (or at least a flexible material) which is used to seal thin-walled plastic hoses which are inserted into the body cavity during surgery. The description states that when the interior of the sleeve is filled with a gaseous or liquid substance, the sleeve closes the cross-section to be sealed while tapering or loosening it as necessary. The sealing sleeve described in the description can be operated hydraulically or pneumatically and thus it is possible to fully or partially close the cross-section of the connection between the cavity and the external environment or fully release it as required, thereby enabling fine tools to be used without difficulty. .

The sleeve that can be used in minimally aggressive surgery is the subject of unpublished patent application PCT / IE94 / 00045 under the name Device used in surgery. The purpose of the prior art sleeve is to provide a controlled pressure environment within the sleeve, while allowing the surgeon's hand to pass through the sleeve. During surgery, gas is injected into the patient's body cavity and the sleeve is designed to prevent gas from escaping from the body cavity while allowing the surgeon to perform the surgery without using aggressive surgical methods. The patent application proposes a sleeve having a flange at the distal end which is provided with adhesive material and which folds to adhere the device to the patient's body, or alternatively has a fitting ring at the distal end that surrounds the incision made in the patient's body. Among other things, the device has the disadvantage that the sleeve protrudes upward from the patient's body and can interfere with the surgical team during work.

The prior art also has the disadvantage that the sleeve includes a seal that seals the sleeve at the top of the surgeon's forearm, and the surgeon must attach the seal to the forearm himself. This seal must be effective enough to prevent gas leakage.

Another problem associated with the use of this sleeve according to patent application PCT / IE94 / 00045 is the phenomenon known as swelling. This means that when the sleeve adheres to the patient's skin or dressing material (known as sterilized dressing material or surgical mask), which may alternately adhere to the skin, the sleeve may tend to pull away from the patient's skin while lifting upwards from the skin. the abdomen of the patient that is

Inflated with the surgical gas used. Sterilized dressing material is also known as a surgical or surgical drape. These terms will be used in the following description.

During surgery, the surgeon generally relies on the trocar and trocar sleeve to secure access to the abdominal cavity while maintaining the pneumoperitoneum. The trocar must be sharp to penetrate and separate the muscles and fascias that surround the abdominal cavity. The trocar sleeve allows the tool to enter and exit through the sleeve while sealing the pneumoperitoneum. At the entrance to the trocar sleeve is a valve that opens to allow surgical instruments, such as dissecting forceps, sewing tools, and medical scissors, to pass through the trocar sleeve into the abdominal cavity where the surgeon can manipulate them.

Obviously, the size of the surgical instruments must be chosen to pass through the trocar sleeve.

The prior art device has the disadvantage that if a surgeon needs to use another instrument that is larger than the trocar diameter, he must incision the patient to reach the tissue or organ he wants to remove. Such surgery causes loss of pneumoperitoneum.

A surgical mask is a thin film of a polymeric material usually made of polyethylene. It is transparent with a fine adhesive on one side and a smooth non-sticky side. The adhesive side is applied to the patient's body over the entire surface of the abdomen or chest, taking care not to create air pockets that could cause poor adhesion of the device to the patient's body. The role of these drapes is to isolate the transfer of microorganisms from the patient's skin surface during surgery to the incision. The surgeon can cut through the veil without compromising the adhesion of the veil to the skin, even in the region just around the incision.

The adhesive properties of the surgical drapes are known to require little force to remove them from the edges of the device, and have a high tensile strength (if someone is looking for attachment at the perimeter of the drapes). This is due to the elastic properties of the drape and the large surface of the drape adjacent to the patient.

A component is required to anchor to the veil. In the prior art, the anchoring is realized with a double-sided adhesive tape attached to the polymer flange.

The present invention seeks to alleviate the drawbacks of a prior art surgical apparatus.

SUMMARY OF THE INVENTION

The first aspect expresses the fact that the present invention, in accordance with the prior art, provides an access opening usable in surgery that includes a sleeve with an outlet opening located at the distal end that is inserted into a cutting wound in the patient's body, an outlet opening allowing access to the patient. the seal of the outlet opening which is inserted into the cut wound, where upon inflating the body cavity with gas, the seal prevents leakage of gas from the cavity while allowing the surgeon's hand or surgical instrument access to the body cavity.

The inlet aperture is located at the proximal end of the sleeve and is also provided with a seal to seal the device in the inlet region where, when inflating the body cavity with gas, it helps prevent gas leakage while allowing the surgeon to enter the cavity and seal his arm. opening.

The inlet seal may include an inflatable chamber that is located at the proximal end of the sleeve. The chamber may be inflated by means of a valve separate from that used to inflate the body cavity. When the access port is in operation, gas is allowed between the inflated chamber and the patient's body cavity to equalize the pressure in the inflated chamber and the body cavity.

The sleeve may include a flange provided with an adhesive to seal the access opening to the outer surface of the patient's body. The skirt may be positioned between the proximal and distal ends of the sleeve such that in operation, when the skirt adheres tightly to the patient's body,

The distal end of the sleeve is inserted through the cut wound into the patient's body and protrudes slightly above the patient's body through the access opening.

When the distal end of the sleeve is inserted into the cut wound, muscle tissue may act as a seal and seal the middle portion of the sleeve between the distal end and the proximal end.

The inlet seal may comprise an inflatable chamber located around the sleeve, which is capable of exerting pressure on the sleeve that at least partially collapses, thereby sealing the inlet opening.

The inflatable chamber does not need to be connected to the sleeve by the gas used, so that in use the chamber is not in contact with the patient's body cavity by gas, whereby the pressure inside the chamber may differ from the pressure in the patient's body cavity.

Alternatively, the inflatable chamber may, by gas, be in communication with the sleeve.

The inflatable chamber generally has an hourglass shape that defines an upper and a lower chamber, wherein the lower chamber may be inserted into a incision in the cavity of the patient's body.

The sleeve and the inflatable chamber may be coaxial and include layers of resilient gas-permeable material that are glued together at a common proximal end where the sleeve is within the inflatable chamber 15 nearer. The chamber may be defined between an outer sleeve located around the inner sleeve, the flap formed between two additional layers of resilient material extending from the proximal end towards the distal end.

The distal ends of the flap may have a branched structure, whereby the layers and the ends of the flap may deform towards each other to form a seal under pressure in the chamber.

The flap may be attached to the inner and outer sleeves at two locations along each side, the flap region between the two locations adapting to the surface of the surgeon's hand or arm.

The inner and outer sleeves may be joined together at specified locations to separate the upper and lower sub-compartments which are in contact with each other by gas, defining at least one adjacent seal of the surfaces constituting the inlet seal 25 or a portion thereof when pressurizing the sub-compartment. The joints may comprise a plurality of opposed welds.

The outlet seal has sleeve layers capable of deforming due to gas pressure within the abdominal cavity at adjacent or more distal ends of the sleeve.

In the distal region of the sleeve, a separate tensioning device may be provided to tension the layers in a generally transverse direction, thereby creating a tension region on the sleeve which would also act as an additional seal and which would be part of the outlet seal.

The tensioner may comprise a pair of opposing arcuate bands that prevent the sleeve from sliding out of the abdominal cavity. Ailerons may be provided at the side edges to provide anchorage points for opposing arcuate strips.

Overview of figures in the drawing

The invention will now be described in more detail with reference to the accompanying drawings, in which, by way of example, various embodiments of a surgical apparatus according to the invention are shown.

Giant. 1 is a perspective view of a first embodiment of an access aperture assembly according to the present invention, wherein the proximal end of the device is shown above; FIG. 2 is a perspective view of a first embodiment in which part of the device 40 is removed for clarity; FIG. a bottom view of a first embodiment of the invention, Fig. 4 shows a perspective view of a second embodiment of the access opening according to the invention, Fig. 5 shows a perspective view of a second embodiment of the device with a cut away part,

Fig. 6 shows another perspective view of the second embodiment with the portion cut away; Fig. 7 shows another perspective view of the second embodiment; Fig. 8 shows a cross section of the second embodiment; Fig. 9 shows a cross section of the second embodiment at right angles; 8, 10 (I) schematically shows a front view of the access opening without any transverse weld lines, and where the opening of the procedure is inserted into the incision of the patient's body, FIG. 10 (II) schematically shows the front view of the access opening in the inflated state, Fig. 10 (ΠΙ) shows a cross section along line AA in Fig. 10 (H), Fig. 11 (I) is a schematic view of an access aperture showing one weld line, Fig. 11 (Π) shows a cross section section along line AA in Fig. 11 (I), Fig. 12 (I) is a schematic view of the access opening with two weld lines shown, Fig. 12 (I) I) shows a cross-section along line AA in FIG. 12 (I), FIG. 13 (I) and (II), and (ΙΠ) are schematic views of the access opening with the interposed flap shown, FIG. 14 (I) shows a front view of the third Fig. 14 (II) shows a cross-section along line AA in Fig. 14 (I), Fig. 15 is a perspective view of a third embodiment of the device; Fig. 15 (I) shows a cross-section along line AA in Fig. 15, Fig. 16 is a plan view of the third embodiment; Fig. 17 is a plan view of the third embodiment showing the device as viewed from the rear end; Fig. 18 (I) shows a more detailed view of the distal end of the third and fourth embodiments; 19 is a cross-sectional view of another embodiment of the access opening, FIG. 20 is a side view of a surgical instrument with a detachable tool head in an exploded view Fig. 21 shows a side view of a trocar sleeve in a state where the head is separated from the shaft of the surgical instrument.

DETAILED DESCRIPTION OF THE INVENTION

Referring to Figures 1, 2 and 3, there is a first embodiment of access opening 1 wherein access opening 1 comprises a sleeve 2 having a proximal end 3 and a distal end 4. The proximal end 3 comprises a skirt 5 and an inflatable chamber 6 having an inlet opening 7 ( mouth) through which the surgeon's hand can enter the sleeve.

In surgery, it is preferred that the incision is guided along the patient's muscles and not across the patient.

To securely attach the access opening 1 to the patient's body, a sterile dressing material may be used which closely fits the body, thereby allowing the incision to pass through the dressing material. The distal end 4 of the sleeve 2 is inserted into the incision and is pushed into the body cavity of the patient (which is not yet filled with gas at this stage) until the flange 5 contacts the dressing material or the skin of the patient if the adhesive dressing material has not been used. The adhesive flange 5 is then tightly applied to the dressing material or skin, thereby firmly attaching the access opening 1 to the patient's body. The muscle tissue reaction around the incision acts

-4US 286383 B6 by pushing the muscle tissue against the sleeve 2.

In order to seal the inlet opening 7, gas is inflated into the inflatable chamber 6, the chamber sealing the inlet opening 7. The patient's body cavity is then inflated. The gas used to fill the chamber 6 enters it through various valves which are also used to inflate the body cavity.

Since the gas connection between the chamber 6 and the body cavity is possible using the access port 1, the pressure in the inflated chamber 6 is the same as the pressure in the body cavity. The portion of the sleeve 2 that is placed in the inflated abdominal cavity during the procedure is also under inward pressure due to the pressure existing in the patient's abdominal cavity, causing the portion of the sleeve to deform to form a perfect seal.

In the event that the surgeon decides to pass the hand provided with the glove through the access opening 1, he pushes the hand through the inlet 7 through the sleeve 2. As the surgeon pushes the hand through the inlet 7, the inflated chamber 6 seals his forearm. Since this creates a seal around a large area of the surgeon's forearm, which is the case in the prior art, blood access to the fingertips is not limited. As the surgeon pushes the hand through the incision, the muscle tissue in the incision area acts to clamp the sleeve 2, thereby forming a seal around the surgeon's forearm. As a result, there is a double seal, one formed around the forearm due to muscle tissue activity, and the other at the inlet opening 7 of the access opening 1 where the inflated chamber 6 forms a seal around the upper part of the forearm.

Once the surgeon pulls the hand out of the access port 1, according to the present invention, the muscle tissue grips the sleeve 2 around the incision, and so at this point the seal remains after the hand has been pulled out of the inlet port 7.

A further advantage of the access opening according to the invention is that the access opening can be handled with one hand. The prior art device required both hands to be used to pull out the hand performing the procedure. In addition, since the distal end 4 of the sleeve 2 is within the patient ' s body, there is no contact of the cut wound with the infected tissue which would otherwise get out of the surgical site and get caught on the hand or on a tool.

It is understood that the size of the access opening can be varied so that, for example, only a finger can be used instead of the entire hand, or the size of the opening can be adapted to the dimensions of the tool. It is also obvious that the size of the opening must be adjusted so that the surgeon can push the instrument through the sleeve by holding it in the hand.

The access opening assembly may be made of any flexible, gas impermeable, sterilizable, biocompatible material, such as polyethylene.

In Figures 4 to 7, the access port assembly druhého of the second embodiment includes an inflatable chamber with the upper chamber 12 and the lower chamber 13, which are in contact with the gas and have an inlet tube 14, through which gas is supplied to both the upper and lower chambers. and into the lower chamber 14 of the inflatable chamber. A separate tube is used to inject gas into the patient's abdominal cavity. The access aperture assembly zahrnuje also includes an adhesive skirt 15 that can be sealed to the patient's skin or dressing material when used. The upper chamber 12 includes an edge 16 that defines an inlet opening 17 at the proximal end 18 of the sleeve 21 that leads to an outlet opening 19 at the distal end 20 of the sleeve 21. The access opening assembly Γ has the advantage that the pressure in the chamber can be controlled independently of pressure in the patient's abdominal cavity. As a result, the pressure in the cavity and in the chamber of the access opening assembly may be different.

If the surgeon wishes to use the access opening assembly,, the gloved hand will pass through the inlet opening 17 of the assembly downward into the sleeve 21. The incision on the patient's body is made to extend along the muscles and not across. The distal end 20 of the sleeve 21 is inserted into the body cavity together with the lower portion 13 of the chamber (the cavity is not yet filled with gas) until the flange contacts

The patient's access hole assembly Γ securely attaches to the patient's skin.

To use the assembly, gas is blown into the chamber through the tube 14 until both the upper and lower chambers 12 and 12 are completely inflated. The response of the muscle tissue around the incision causes the muscle tissue to press against the wavy zone 22 defined between the just inflated upper chamber 12 and the inflated lower chamber 13.

The body cavity then inflates. Since gas contact is not possible between the body cavity and the chamber of the assembly, the pressure in the chamber 6 and the body cavity may not be the same.

The pressure in the chamber exerts a pressure inward of the sleeve, and as shown by the sleeve 21 in FIG. 6, this occurs along the area indicated by A. Similarly, the portion of the sleeve 21 located within the inflated abdominal cavity is under inward pressure, it deforms under pressure in the abdominal cavity as indicated by the letter B in Figs. 6 and 7, thereby forming at the distal end of the seal assembly. Areas A and B act as seals to prevent leakage of gas from the patient's abdominal cavity. In addition, they encircle the upper and lower parts of the surgeon's forearm as his hand is inserted over the sleeve into the patient's abdominal cavity.

8 and 9, the access opening consists of an outer sleeve 30 and an inner sleeve 31. The applied pressure causes the outer sleeve 30 to inflate, thereby deforming the inner sleeve 31 and acting as a seal in the access passage to the abdominal cavity. This additional feature increases the effectiveness of the gasket especially when the surgeon pulls the hand out of the sleeve.

The outer sleeve 30 is connected to the inner sleeve 31 at locations 32 completely opposite. This leads to local pressure on the outer sleeve, creating two wells on the outer sleeve. The resulting force F acts on the inner sleeve so that the walls of the inner sleeve contact. (This is similar to the phenomenon that occurs when the balloon is inflated and the throat is stretched laterally, instead of the throat being ligated). As a result, the pressure of the gas in the abdominal cavity is required to overcome the pressure that caused the inner sleeve to deform and the force-closing action F to occur due to gas leakage.

A preferred embodiment of the present invention will now be described, as shown in Figs. 10 to 18. The access opening of this third embodiment is derived from the described third embodiment and is a continuation thereof. The access opening 40 includes an inner sleeve 41 and an outer sleeve 42. The outer sleeve 42 has a skirt 44 located at the distal end of the sleeve. The access opening of this third embodiment will be described first in Fig. 10. In use, the access opening is fixedly attached to the outside of the patient's abdominal wall when a surgical drape is used or not when the inner sleeve 41 penetrates the abdominal cavity (see Fig. 10). AND)). As is usually the case with minimally aggressive surgery, the abdominal cavity is inflated with gas by pressure P, as shown in Figure 10 (II). The gas expands in the abdominal cavity. (The gas pressure always acts perpendicularly to the surface of the enclosing walls). Gas leakage around the cut wound results in gas entering the chamber formed between the inner sleeve 41 and the outer sleeve 42. The gas is pressurized through a control valve (a conventional tap valve) connected to the outer sleeve 42. The gas inflates the outer and at the same time causes the opposite sides of the inner sleeve 41 to be pushed together so that they touch. As a result, as shown in Fig. 10 (Π), a chamber 46 is formed between the inner sleeve 41 and the outer sleeve 42. This chamber effectively seals the abdominal cavity from atmospheric pressure outside the abdominal cavity of the patient. The force that keeps the inner sleeve sealed corresponds directly to the pressure in the abdomen, and the greater the gas pressure, the greater the force that produces the sealing effect.

As seen in Fig. 10 (Π), the outer sleeve 42 forms a cylinder when inflated. The diameter of the cylinder D is determined by the circumference C of the outer sleeve 42. The inner sleeve 41 is connected at opposite points circumferentially to the outer sleeve 42. The nominal diameter of the inner sleeve 41 is smaller than the diameter of the outer sleeve 42 so that the outer sleeve 42 is attracted to the inner sleeve 41 its diameter is thus equal to the diameter D. Upon introduction of the gas pressure into the outer sleeve 42, the outer sleeve 42 forms a cylinder of nominal diameter D that keeps the inner sleeve 41 tightly in a transverse plane.

-6GB 286383 B6

Upon introduction of the gas into the structure shown in Fig. 10 (II), there are difficulties in sliding the hand and arm through the access passage as the inner sleeve 41 snaps tightly to the hand and arm. The surgeon must push his hand through the inlet passage against the gas pressure applied to the inner sleeve 41. This problem is solved by the embodiment shown in Figures 11 (I) and (II), in which the inner sleeve 41 is welded at certain points to the outer 14. As a result of the weld along line 45, the outer sleeve 42, when inflated, pulls the inner sleeve 41 outwardly as shown in Figure 11 (II). Since the weld line 45 does not extend along the entire width of the inner and outer sleeves 41, 42, gas can penetrate beyond the weld line as shown in Figure 11 (II), inflating the chamber between the inner and outer sleeves, resulting in the formation the upper sub-chamber 48 and the lower sub-chamber 47. Since the upper sub-chamber 48 is subjected to gas pressure, the walls of the upper portion of the access passage are still held in contact with each other to form a seal 100. The ideal distance between the upper seal 100 and the distal end of the inner sleeve 41 greater than the distance between the surgeon's wrist and the fingertips, which would ensure that, when the hand is inserted into the access opening, the surgeon's wrist will seal before the fingers reach the distal end of the inner sleeve 44.

The ease of access through the access opening is increased by the inclusion of additional weld lines 45, 45 'between the inner and outer sleeves as shown in Fig. 12. Including the weld line 45' creates an additional line of seal 101 in Fig. 12. forming an upper sub-chamber 48 'and a lower sub-chamber 47' between the inner sleeve 41 and the outer sleeve 42, which further increase the stiffness of the access opening and hence the ease of access for the surgeon's hand.

The efficiency of the upper seal 100 is further enhanced by the properties of a flap having a so-called branched structure (see FIGS. 13, 14, 15 and 16). The branching of the edges is achieved by the diameter of the lower end of the valve being greater than the inner diameter D, so that the branched ends have to be pushed in to achieve the same diameter as D. The edges allow the gas to pass between the flap 50 and the inner sleeve 41 and The valve allows you to work the way you want and adapt to the surgeon's arm. The branched edge is only required to extend inwardly from the line of the top seal 100. The attachment of the flap 50 to the inner sleeve 41 is realized at positions A and B shown in Fig. 13 (II). This prevents the attachment of the flap 50 to the inner sleeve 41, resulting in greater rigidity and greater adaptability to the surgeon's arm. Finally, in the event that no gas leaks through this combination of gaskets, the outer sleeve 42 is tapered so that the final state of the gasket can be reached between the edge of the mouth of the access opening and the surgeon's forearm. As shown in FIG. 10, the gas pressure required to seal the inner sleeve causes the access opening to be subjected to a force F which causes the inner sleeve 41 to tend to turn inside out. To avoid this, the inner and outer sleeves are welded together along a line identical to their seams as shown in Figs. 15 and 16. This solves the problem of the inward turning tendency of the proximal end of the inner sleeve 44. the end of the inner sleeve 41 that extends into the abdominal cavity may still be inclined to turn the inside out.

The tendency of the distal end of the inner sleeve 41 to invert due to inflation pressure is overcome by the inclusion of a resilient arcuate tensioning device comprising the arcuate belts 55 shown in Figures 14, 15, 16 and 18. The inner sleeve 41 is modified by adding two wings 56. the sleeve is slit because of the inclusion of the wings 56 as protection. The wings 56 are welded together by a short linear weld. This results in rigid wings 56. The wings 56 provide an anchoring area for the tensioning device. The two arcuate strips 55 are welded to each other via the fins 56, forming a joint with each other.

The arcuate strips 55, when compressed during assembly, exert a tension on the inner sleeve 41 and cause the opposing sides 104 of the inner sleeve 41 to contact and thereby form a prime seal without actuating the inflation gas pressure. The eventual use of gas pressure results in the formation of additional seals as described. The geometry of the arcuate strips 55 is such that when positioned at right angles to the cutting wound, they may pass through the cutting wound. Once in the abdominal cavity, the belts 55 join in parallel with the abdominal wall. In this position, the pressure of the injected gas acts to reverse the inner sleeve, but since the arcuate strips cannot pass through the cutting wound,

-7EN 286383 B6 the inner sleeve is held in the normal position. The stiffness resulting from the short linear welds in the wings 56 and in combination with the fact that the arcuate strips are welded to the ailerons, holds the wings 56 perpendicular to the arcuate strips, thereby preventing the distal end of the inner sleeve from turning.

The use of the device according to the third embodiment will now be described in more detail.

Without (or with) a surgical drap, a suitable incision can be made through the abdominal wall to penetrate the peritoneum. The distal end of the access opening 40 is inserted into the cut wound and the tensioning device is forced into the peritoneal cavity. An adhesive connection is made between the skirt 44 and the patient's skin or surgical mask when the mask is used. All parts of the access port 40 at this stage are exposed to atmospheric pressure. Assuming that the gas inlet opening is located, gas is forced into the patient's abdominal cavity under pressure.

By extending the inner sleeve in the transverse direction, the arcuate strip provides a powerful seal to the inner sleeve. Upon introduction of the gas, the gas may pass around the cutting wound, resulting in the sub-chambers 48, 47, 46 being filled with gas (see FIG. 14). As previously described, the device inflates and the inner sleeve forms a top seal 100 and a middle seal 101. Due to the presence of gas at the distal end of the inner sleeve 41, the bottom seal 102 is strengthened. activity.

The surgeon now passes his hand over the top seal 100 and the middle seal 101. His hand passes through the cut 20 wound toward the bottom seal 102. At this point, his wrist is in the top seal 100. Further forward movement results in the bottom seal 102 opens. Gas escapes around the fingers and enters cavities A and B. The flap is now subject to a pressure that differs from atmospheric pressure on one side and compressed gas on the other. This causes the branched edges of the flap 50 to conform to the shape of the surgeon's forearm, thereby forming an additional 25 gasket 103. The bottom gasket 102 is not active at this time. The surgeon can now move his hand further into the abdominal cavity, usually as far as his hand reaches the far end of the inner sleeve. The gas remains sealed by the upper seal 100. In the event that due to hand movement the gas begins to escape around the upper seal 100, the gas pressure in the cavity A drops below the value of the compressed gas. If a gas leak occurs around the middle seal 101, the pressure in the cavity 30 B also drops below the value of the compressed gas. If this happens, there will be a gas pressure difference on the bottom seal which becomes active and causes the inner sleeve to conform, at the distal end of the inner sleeve, to the shape of the surgeon's hand, thereby enhancing the sealing capability of the inner sleeve at this point. If, by chance, the bottom seal is opened due to further hand movement, the gas will leak into cavity A, causing the top seal to become active. It is clear that the device is configured such that the error of one seal automatically activates the next seal.

Assuming that the top seal 100 is active, the extraction to the surgeon's hand will proceed as follows. The withdrawal of the hand until the wrist reaches the upper gasket 100 will not cause anything except that the arcuate band by its elasticity causes the lower gasket 102 to remain closed. Once the hand enters the upper seal 100, an escape route is created for the gas and the gas 40 can escape into the atmosphere. Immediately the pressure in cavities A and B drops, which again causes the pressure difference on the bottom seal to become fully active. If the bottom seal was active at the beginning of the hand movement, the passage of the hand through the seal creates an escape route and the top seal 100 immediately becomes active.

After the hand is pulled out, the inner sleeve 41 will tend to turn. This is prevented by the fact that the 45 arcuate strips 55 cannot pass through the cutting wound in the orientation shown. As previously explained, the stiffness of the wings 56 on the inner sleeve 41 also counteracts inversion. If a reversal occurred, which is very unlikely, the top seal would immediately activate.

The removal of the device after surgery is performed in a relatively straight line. 50 After the gas overpressure has been removed when the device is collapsed, the adhesive strip breaks at the flange.

-8GB 286383 B6

This allows the arcuate strips to be reoriented by introducing a narrow edge into the cutting wound. The gentle pulling of the welded seam of the inner sleeve 41 causes the end of the arcuate strip 55 to enter the cut wound where it can tightly grip and pull. The access opening essentially consists of a flexible tube made of a polymeric film, the edges of which are welded, and a flange coated with an adhesive material and also made of a flexible polymeric film. The tube is partially inverted, as shown in Figure 10 (I), that the end of the tube that is not attached to the flange extends beyond the flange. This arrangement forms the inner and outer sleeves as described. For ease of manufacture, the walls of the inner sleeve are made separately from the outer sleeve and are welded to the outer sleeve together with the material that forms the branched edge of the flap 50. The flap 50 is made by welding two additional pieces of polymer film to form the flap 50 inside the inner sleeve.

Figure 19 illustrates an access aperture assembly 110 according to a fourth embodiment of the invention, which is made up of two portions, a bottom portion 115 and a top portion 120. Both portions 115 and 120 have a flange 125 that can be joined together by an adhesive or other mechanism . The lower portion 115 has an escape route 130 that can be opened after joining the portions 115 and 120 by peeling away the label (above the escape route). In all other respects, the device is similar to the third embodiment of the access opening assembly described above.

20 and 21, a surgical instrument 201, according to a second aspect of the present invention, comprises a handle 202 provided with a trigger 203 that is rotatably coupled to the handle 202. The handle 202 also includes an elongated shaft 204 and a attachable tool head 205. the head may be connected to each other by a fastener 206. As shown in the drawings, the tool head 205 has a stapling device. However, any alternative tool, such as a medical forceps, can be mounted to the tool head 205.

In use, the shaft 204 of the surgical instrument 201 is inserted into a valve (not shown) on the trocar sleeve 210. The shaft is forced through the cylinder 211 of the trocar sleeve 210 having an inside diameter of approximately 3 to 6 mm. In the prior art, the trocar cylinder has an inner diameter as well as a shaft of up to 15 mm, which diameter corresponds to the tool head to be mounted thereon.

In use, the surgeon holds the tool head 205 in the hand, the tool head 205 with the associated tools being attached to the shaft 204 by the fastener 206. The trigger 203 is actuated by the surgeon so as to manipulate the stapling device disposed on the detachable tool head 205.

It will be appreciated that the fastener 206 is variable, depending on the dimensions of the tool head 205, since this is not limited in size by the size of the trocar sleeve 211.

Another reference relates to a surgical drape of the present invention.

There are four main ways to use a surgical mask:

1. The invention may be used as a fastening means for a device such as an access device or access opening during minimally aggressive (invasive) surgery as previously described, when a relatively high force exerted on the instrument must be applied the pressure of the gas that is used in pneumoperitoneum, or arises when manually accessing the access opening or from the tool used.

2. It can be used as a fastener where it is desired that the tool to be used, for example, the various ducts used in minimally aggressive procedures, do not leak gas. In this case, the device must be made flush with the adhesive bead used with the adhesive flange adhering to the drape. It can also be used to secure these devices to appropriate locations so that they do not slide through a stroked puncture, and are used when the surgeon intends to insert a smaller cannula than the puncture would allow.

3. In addition, the invention may be used as a means for exerting external tensile force on the patient ' s skin and attached tissue (subcutaneous tissue, muscle, peritoneum) as a multipurpose tissue.

-9EN 286383 B6 Product. One purpose is to use it as a means to raise the abdominal wall without using gas to form a cavity, similar to a pneumoperitoneous cavity, or to use gas-free laprolift, which uses an internal device to raise the abdominal wall for procedures in which no gas is used. Another purpose is to raise the abdominal cavity to make the first throat incision safer. It can also be used as a tissue retractor, by pulling at the attachment points of the drapes on both sides of the wound.

4. Surgical drapes can also be used in a gas-pull combination where less gas pressure is required. Similar to point 3, tension-inducing means at the attachment points are used herein to reduce the amount of gas pressure required to create the cavity needed for minimally aggressive surgery. For example, if someone had to stretch an access opening to the arm of the prior art, they needed less gas pressure to fill the body cavity and create the same space than would be necessary using the pressure alone. Gas pressure brings complications to selected patients and is sometimes difficult to work with, so this technique provides significant benefits, for example, in minimally aggressive surgery.

It is to be understood that the invention is not limited to the specific details which have been set forth herein and which only relate to the examples given, but that various modifications and changes are possible within the scope of the invention as defined in the appended claims.

Claims (20)

PATENT CLAIMS An access opening for use in surgery comprising a sleeve (2) having an inlet opening (7) located at the distal end (3) of the sleeve (2) and an outlet opening allowing access to the patient's body cavity located at the proximal end (4) a sleeve (2) for introducing the sleeve into a cutting wound in a patient's body, comprising an outlet opening seal (102) provided with the sleeve (2) deforming gas pressure within the patient's body cavity or adjacent the sleeve edge (2) 2) wherein, when the body cavity is inflated with gas, the outlet seal (102) prevents leakage of gas from the cavity of the patient's body through the sleeve (2) while providing access to the surgeon's hand or surgical instrument. An access opening according to claim 1, characterized in that the inlet opening (7) is provided with an inlet seal (100) for sealing in the region of the inlet opening (7) which prevents gas leakage from the patient's body cavity when inflated. provide access for the surgeon's hand and a seal around the hand remaining outside the access opening. An access opening according to claim 2, characterized in that the inlet seal (100) comprises an inflatable chamber (48) located at the proximal end (3) of the sleeve (2). The access opening of claim 2 or 3, wherein the sleeve (2) comprises a skirt (44) having adhesive material thereon for externally securing the access opening assembly to the patient. The access opening of claim 4, wherein the skirt (44) is located between the proximal end (3) and the distal end (4) of the sleeve (2) and when the skirt (44) is attached to the patient's body, the distal end ( 4) inserting the sleeve (2) through the incision into the patient's body cavity and the access opening extends through a short section from the patient's body. Access opening according to any one of the preceding claims, characterized in that the sleeve (2) has a portion between the distal end (4) and the proximal end (3), and The distal end (4) is inserted into the incision in the body, the muscle tissue around the incision acts as a seal that seals the middle portion of the sleeve (2) between the distal and proximal ends (4,3). Access opening according to any one of the preceding claims, characterized in that the inlet seal (100) comprises an inflatable chamber (12, 13) surrounding the sleeve (2) and exerting pressure on the sleeve (2), thereby at least a portion of the sleeve (12). 2) deforms and seals the inlet opening (7). Access opening according to any one of the preceding claims, characterized in that the inflatable chamber (12, 13) is free of gas-sleeve connection so that the chamber is free of gas-connection to the body cavity of the patient and thus the pressure inside the chamber is different from the pressure inside. patient's body cavity. Access opening according to any one of claims 3 to 7, characterized in that the inflatable chamber (12, 13) is connected to the sleeve by gas. Access opening according to either of claims 7 or 8, characterized in that the inflatable chamber has an hourglass shape and forms an upper chamber (12) and a lower chamber (13), the lower chamber (13) being insertable into the cutting wound in the the cavity of the patient's body. Access opening according to claim 3, characterized in that the sleeve and the inflatable chamber are coaxial and comprise a layer of resilient, gas-impermeable material bonded at the common proximal end (3) and side edges, the sleeve (2) being positioned within the inflatable chamber in the nearer area. The access opening of claim 11, wherein the chamber is defined between an outer sleeve (42) disposed around the inner sleeve (41) in a proximate region, and within the inner sleeve (41) extending from the proximal end to the distal end. is a flap (50) positioned between two further layers of resilient material. Access opening according to claim 12, characterized in that the distal edges of the flap (50) have a branched structure and the layers and the ends of the flap (50) are deformable to each other to form a seal in the event of the chamber inflating. Access opening according to claim 12 or 13, characterized in that the flap (50) is connected to the inner and outer sleeves (41, 42) at two locations along each side thereof, wherein the flap region (50) between the two locations is the flexible part of the surgeon's hand or arm. Access opening according to claims 1-4, characterized in that the inner and outer sleeves (41, 42) are connected by joints at specific locations and divide the inflatable chamber into upper and lower sub-compartments (46, 47 ', 48) which are by means of gas in conjunction, upon inflation of the sub-chamber, they define at least one associated surface seal (100, 101) forming the inlet seal or a portion thereof. The access opening of claim 15, wherein the joints comprise opposed weld lines (45, 45). The access opening of any one of the preceding claims, wherein the sleeve (2) comprises layers of resilient, gas impermeable, sterilizable, biocompatible material that deforms by gas pressure within the abdominal cavity of the patient at or adjacent the distal edges of the sleeve. -11 CZ 286383 B6 An access opening according to claim 17, characterized in that in the distal region of the sleeve there is a separate tensioning device (55) stretching the layers in the transverse direction, thereby creating a tension region across the sleeve acting as a further seal (104) which is part of the outlet seal. 5 The access opening of claim 18, wherein the separate tensioning device comprises a pair of opposing arcuate bands (55) preventing the sleeve from sliding out of the abdominal cavity. An access opening according to claim 19, characterized in that wings 10 (56) are formed in the side edges of the sleeve providing anchor points for the opposing arcuate strips (55).